Gypsum board manufacturing method and manufacturing device

Abstract

As a lower forming plate 8, a forming plate having: a lower plate main body 10 constituted from an electrically conductive material; and a lower embedded electrode 12 embedded in the lower plate main body 10, the lower embedded electrode 12 being electrically insulated from the lower plate main body 10 by an insulator 14 and being embedded so as for a portion thereof to be exposed on the surface of the lower plate main body 10 making contact with a lower lining paper sheet 16 is used.

Claims

1. A method for producing a gypsum board, the method comprising: continuously injecting a gypsum slurry into a gap between a pair of upper and lower lining paper sheets while continuously supplying the pair of upper and lower lining paper sheets, so as to form a laminated material; and allowing the laminated material to pass between a pair of upper and lower forming plates so as to form a molded body having a thickness corresponding to a space between the upper and lower forming plates, wherein at least one of the upper and lower forming plates comprises: a plate main body comprising an electrically conductive material; and an embedded electrode embedded in the plate main body, wherein the embedded electrode is electrically insulated from the plate main body by an insulator and is embedded so that a portion of the embedded electrode is exposed on a surface of the plate main body, where the plate main body contacts the lining paper sheet, a circuit is completed by electrically connecting the plate main body and the embedded electrode embedded in the plate main body, and a voltage is applied to the circuit, and whenever the lining paper sheet adjacent the embedded electrode is cut, the plate main body and the embedded electrode contact with the gypsum slurry, electric current flows in the circuit, and the space between the pair of upper and lower forming plates is expanded until the electric current flows are broken, and thereafter the space between the pair of upper and lower forming plates is restored to the original space.

2. The method for producing a gypsum board according to claim 1, wherein the embedded electrode is embedded in the plate main body at a portion on a downstream side relative to a starting position of forming the gypsum board, where the starting position of forming the gypsum board is defined as one of the following (1) and the following (2), whichever is located at a more downstream side: (1) a position of an upstream end of either one of the pair of upper and lower forming plates; and (2) a position of a downstream end of a taper portion if present in an embodiment, wherein the taper portion is formed on at least one of the pair of upper and lower forming plates, a plate thickness of the taper portion becomes thinner toward the upstream ends of the forming plates, and the space between the pair of the forming plates becomes larger toward the upstream ends of the forming plates, corresponding to the plate thickness.

3. The method for producing a gypsum board according to claim 2, wherein the embedded electrode is embedded in the plate main body between the starting position of forming the gypsum board and a position of 50 mm to a downstream side from the starting position.

4. The method for producing a gypsum board according to claim 1, wherein the insulator comprises at least one material selected from the group consisting of phenol resin laminated plates with a cloth base material, phenol resin laminated plates with a paper base material, epoxy resin-impregnated glass fiber cloth, and epoxy resin-impregnated paper.

5. The method for producing a gypsum board according to claim 1, wherein the electrically conductive material is at least one material selected from the group consisting of iron materials, stainless steel materials, and aluminum materials, or a material obtained by applying hard chromium plating thereon.

6. An apparatus for producing a gypsum board, comprising: a pair of upper and lower forming plates for forming a laminated material, wherein the laminated material is obtained by injecting a gypsum slurry into a gap between a pair of upper and lower lining paper sheets, and a thickness of the laminated material corresponds to a space between the plates, wherein at least one of the pair of upper and lower forming plates comprises: a plate main body comprising an electrically conductive material; and an embedded electrode embedded in the plate main body, wherein the embedded electrode is electrically insulated from the plate main body by an insulator and is embedded so that a portion of the embedded electrode is exposed on a surface of the plate main body, where the plate main body contacts the lining paper sheet, a circuit is completed by electrically connecting the plate main body and the embedded electrode embedded in the plate main body, and the apparatus further comprises: an electric current detector, which is electrically connected to the circuit; and an actuator, which moves at least one of the forming plates, up and down in response to an electric signal from the electric current detector.

7. The apparatus for producing a gypsum board according to claim 6, wherein the embedded electrode is embedded in the plate main body at a portion on a downstream side relative to a starting position of forming the gypsum board, where the starting position of forming the gypsum board is defined as one of the following (1) and the following (2), whichever is located at a more downstream side: (1) a position of an upstream end of either one of the pair of upper and lower forming plates; and (2) a position of a downstream end of a taper portion if present in an embodiment, wherein the taper portion is formed on at least one of the pair of upper and lower forming plates, a plate thickness of the taper portion becomes thinner toward the upstream ends of the forming plates, and the space between the pair of the forming plates becomes larger the taper portion toward the upstream ends of the forming plates, corresponding to the plate thickness.

8. The apparatus for producing a gypsum board according to claim 7, wherein the embedded electrode is embedded, in the plate main body between the starting position of forming the gypsum board and a position of 50 mm to a downstream side from the starting position.

9. The apparatus for producing a gypsum board according to claim 6, wherein the insulator comprises at least one material selected from the group consisting of phenol resin laminated plates with a cloth base material, phenol resin laminated plates with a paper base material, epoxy resin-impregnated glass fiber cloth, and epoxy resin-impregnated paper.

10. The apparatus for producing a gypsum board according to claim 6, wherein the electrically conductive material is at least one material selected from the group consisting of iron materials, stainless steel materials, and aluminum materials, or a material obtained by applying hard chromium plating thereon.

Description

BRIEF DESCRIPTION OF DRAWING

(1) FIG. 1 is a schematic side view schematically illustrating an embodiment of an apparatus for producing a gypsum board of the present invention.

(2) FIG. 2 is a schematic side view schematically illustrating another embodiment of an apparatus for producing a gypsum board of the present invention.

(3) FIG. 3 is a schematic side view schematically illustrating yet another embodiment of an apparatus for producing a gypsum board of the present invention.

(4) FIG. 4 is a schematic side view schematically illustrating an example of a conventional apparatus for producing a gypsum board.

(5) FIG. 5 is a schematic side view schematically illustrating a still another embodiment of an apparatus for producing a gypsum board of the present invention

(6) FIG. 6A is a conceptual diagram schematically explaining a starting position of forming in an apparatus for producing a gypsum board of the present invention.

(7) FIG. 6B is a conceptual diagram schematically explaining a starting position of forming in an apparatus for producing a gypsum board of the present invention.

(8) FIG. 6C is a conceptual diagram schematically explaining a starting position of forming in an apparatus for producing a gypsum board of the present invention.

(9) FIG. 6D is a conceptual diagram schematically explaining a starting position of forming in an apparatus for producing a gypsum board of the present invention.

(10) FIG. 6E is a conceptual diagram schematically explaining a starting position of forming in an apparatus for producing a gypsum board of the present invention.

DESCRIPTION OF EMBODIMENTS

(11) Hereinafter, the present invention will be explained in detail. However, the present invention is not limited to the following embodiments and includes all the objects containing matters used to specify the present invention.

(12) [1] Method for Producing Gypsum Board:

(13) The method for producing a gypsum board relates to a method for producing a gypsum board, the method comprising a step of continuously injecting a gypsum slurry into a gap between a pair of upper and lower lining paper sheets while continuously supplying the pair of upper and lower lining paper sheets to form a laminated material and allowing the laminated material to pass between a pair of upper and lower forming plates to obtain a molded body having a thickness depending on a space between the plates.

(14) For example, any of a production apparatus 1 as illustrated in FIG. 1, a production apparatus 1A as illustrated in FIG. 2, a production apparatus 1B as illustrated in FIG. 3, and a production apparatus 1C as illustrated in FIG. 5 is a production apparatus capable of conducting the production method of the present invention, and with the production apparatuses, the step of continuously injecting the gypsum slurry 4 into the gap between a pair of upper and lower lining paper sheets 2 while continuously supplying the pair of upper and lower lining paper sheets 2 to form a laminated material and allowing the laminated material to pass between the pair of upper and lower forming plates 6 to obtain a molded body having a thickness depending on the space between the plates.

(15) The gypsum slurry is a slurry containing calcined gypsum (-type hemihydrate gypsum and -type hemihydrate gypsum) and water as main components. In the present invention, the gypsum slurry includes a slurry using type III anhydrous gypsum in place of part or the whole of the calcined gypsum. The gypsum slurry may contain an additive such as an adhesion improver, a curing accelerator, or an admixture ingredient in addition to calcined gypsum and water.

(16) The lining paper sheet is a lining paper sheet for producing a gypsum board. In the present invention, the lining paper sheet includes a glass fiber mat for producing a gypsum board. A sizing agent is mixed in the lining paper sheet for the purpose of suppressing water absorption and securing insulation properties during forming. Accordingly, water in the gypsum slurry does not penetrate into a surface layer of the lining paper sheet (a layer on the side not making contact with the gypsum slurry) immediately after the lining paper sheet makes contact with the gypsum slurry, and the lining paper sheet functions as an insulator. The thickness of the lining paper sheet is not particularly limited, however lining paper sheets having a thickness of 0.2 to 1.0 mm are usually used.

(17) The production method of the present invention can suitably be used when gypsum boards are produced at a high speed. Specifically, the production method of the present invention can suitably be used when gypsum boards are produced at a production speed of 60 m/min or more.

(18) [1-1] Forming Plates:

(19) In the production method of the present invention, a forming plate having: a plate main body constituted from an electrically conductive material; and an embedded electrode embedded in the plate main body, the embedded electrode being electrically insulated from the plate main body by an insulator and being embedded so as for a portion thereof to be exposed on a surface of the plate main body making contact with the lining paper sheet is used as at least one of the pair of upper and lower forming plates. By embedding the electrode for detecting the cut of the lining paper sheet in the plate main body, it becomes possible to detect the cut of the lining paper sheet earlier than in the case where the electrode is arranged on the downstream side of the end of the plate main body.

(20) For example, when it is necessary to detect the cut of the lower lining paper sheet, a forming plate having: the lower plate main body 10 constituted from an electrically conductive material; and the lower embedded electrode 12 embedded in the lower plate main body 10, the lower embedded electrode 12 being electrically insulated from the lower plate main body 10 by the insulator 14 and being embedded so as for a portion thereof to be exposed on the surface of the lower plate main body 10 making contact with the lower lining paper sheet 16 is used as the lower forming plate 8, as shown in the production apparatus 1 as illustrated in FIG. 1.

(21) Based on the similar idea, when it is necessary to detect the cut of the upper lining paper sheet, a forming plate having: the upper plate main body 26 constituted from an electrically conductive material; and the upper embedded electrode 28 embedded in the upper plate main body 26, the upper embedded electrode 28 being electrically insulated from the upper plate main body 26 by the insulator 30 and being embedded so as for a portion thereof to be exposed on the surface of the upper plate main body 26 making contact with the upper lining paper sheet 32 may be used as the upper forming plate 24, as shown in the production apparatus 1A as illustrated in FIG. 2.

(22) Further, when it is necessary to detect the cut of both the lower lining paper sheet and the upper lining paper sheet, the lower forming plate 8 as illustrated in FIG. 1 and the upper forming plate 24 as illustrated in FIG. 2 can be used together. That is to say, a forming plate having the lower embedded electrode 12 and the forming plate having an upper embedded electrode 28 are used as the lower forming plate 8 and the upper forming plate 24 respectively as illustrated in the production apparatus 1B in FIG. 3.

(23) Furthermore, an external electrode for detecting the cut of paper can be installed outside of the forming plate in addition to the embedded electrode for the purpose of backing up the embedded electrode. In the production apparatus 1C as illustrated in FIG. 5 for example, a forming plate having the embedded electrode 12 is used as the lower forming plate 8, and a lower external electrode 38 for detecting the cut of paper is further installed outside of the lower forming plate 8. The lower external electrode 38 is arranged on the downstream side of the lower forming plate 8 apart from the lower forming plate 8. Moreover, the lower external electrode 38 is arranged so as to make contact with the lower lining paper sheet 16. In such constitution, a circuit 40 that includes the lower external electrode 38, the lower plate main body 10, and a power source D3 backs up a circuit 18, thereby making it possible to detect the cut of paper in case the cut of paper cannot be detected by the circuit 18 including the embedded electrode 12, the lower plate main body 10, and the power source D1.

(24) In addition, the lower external electrode 38 as illustrated in FIG. 5 can also be installed in the production apparatus 1A as illustrated in FIG. 2 or the production apparatus 1B as illustrated in FIG. 3. In such cases, the effect of backing up a circuit including an embedded electrode (lower embedded electrode 12 or upper embedded electrode 28) such as the circuit 34 illustrated in FIG. 2, and the circuits 18 and 34 illustrated in FIG. 3 can also be obtained by the circuit 40 including the lower external electrode 38, the lower plate main body 10, and the power source D3.

(25) An upper external electrode (not illustrated in figures) can also be used as the external electrode for backup. The upper external electrode is an electrode that is arranged on the downstream side of the upper forming plate apart from the upper forming plate, and is arranged so as to make contact with the upper lining paper sheet. The circuit for backup that consists of the upper external electrode, the upper plate main body, and the power source can detect the cut of paper in the same manner as in the circuit 40 including the lower external electrode 38 as illustrated in FIG. 5, thereby making it possible to obtain the effect of backing up the circuit including the embedded electrode. Accordingly, the circuit including the upper external electrode can be used in place of or together with the circuit 40 including the lower external electrode 38.

(26) In the method for producing a gypsum board of the present invention, the constitution of the lower forming plate and upper forming plate is particularly important.

(27) Specifically, the position where the upper embedded electrode or lower embedded electrode is arranged, the material quality of the insulator, the material quality of the electrically conductive material that constitutes the upper plate main body or lower plate main body, and so on become important. These will be explained specifically in the section of Apparatus for Producing Gypsum Board.

(28) [1-2] Circuit:

(29) In the production method of the present invention, the circuit is constituted by electrically connecting the plate main body and the embedded electrode embedded in the plate main body, and voltage is applied to the circuit. Thereby, it becomes possible to detect the cut of the lining paper sheet when the plate main body and the embedded electrode make contact with the gypsum slurry and an electric current flows.

(30) For example, when it is necessary to detect the cut of the lower lining paper sheet, the circuit 18 may be constituted by electrically connecting the lower embedded electrode 12 and the lower plate main body 10 to apply voltage to the circuit 18 as illustrated in FIG. 1. On the other hand, when it is necessary to detect the cut of the upper lining paper sheet, the circuit 34 may be constituted by electrically connecting the upper embedded electrode 28 and the upper plate main body 26 to apply voltage to the circuit 34 as illustrated in FIG. 2. Further, when it is necessary to detect the cut of both the lower lining paper sheet and the upper lining paper sheet, the circuit 18 may be constituted by electrically connecting the lower embedded electrode 12 and the lower plate main body 10 and the circuit 34 may also be constituted by electrically connecting the upper embedded electrode 28 and the upper plate main body 26 to apply voltage to both the circuit 18 and the circuit 34 as illustrated in FIG. 3.

(31) The voltage applied to the circuit may be an alternating current or a direct current, and it is preferable that the voltage is a low voltage that is not dangerous to an operator when the operator makes contact with the circuit. It is preferable that the voltage is set to, for example, about AC 8V. Further, it is preferable that the lower plate main body 10 and/or the upper plate main body 26 are connected to a ground C as illustrated in FIG. 1 to FIG. 3. Even a small electric potential difference can be detected by connecting these plate main bodies to the ground.

(32) [1-3] Expansion of Space Between Plates:

(33) In the production method of the present invention, the space between a pair of forming plates is expanded when an electric current flows in the circuit (namely, the cut of the lining paper sheet or the like is detected). Thereby, the foreign bodies that have been caught between the pair of upper and lower forming plates easily pass between the forming plates. Accordingly, the lining paper sheet does not continue to be cut due to the foreign bodies, and it never occurs that the lining paper sheet is completely torn and the production is stopped.

(34) In the case where the production apparatus 1 as illustrated in FIG. 1 is used for example, the space between a pair of the forming plates 6 can be expanded when an electric current flows in the circuit 18 (namely, when the cut of the lower lining paper sheet 16, or the like is detected). On the other hand, in the case where the production apparatus 1A as illustrated in FIG. 2 is used, the space between a pair of the forming plates 6 can be expanded when an electric current flows in the circuit 34 (namely, when the cut of the upper lining paper sheet 32, or the like is detected). Further, in the case where the production apparatus 1B as illustrated in FIG. 3 is used, the space between a pair of forming plates 6 can be expanded when an electric current flows in either the circuit 18 or the circuit 34 (namely, when the cut of either the lower lining paper sheet 16 or the upper lining paper sheet 32 is detected).

(35) Examples of the method for expanding the space between forming plates include: (i) a method in which the upper forming plate is lifted while maintaining a state where the lower forming plate is fixed; (ii) a method in which the lower forming plate is brought down while maintaining a state where the upper forming plate is fixed; and (iii) a method in which the upper forming plate is lifted and the lower forming plate is brought down, and so on. The method (i) in which the upper forming plate 24 is lifted while maintaining a state where the lower forming plate 8 is fixed is adopted in any of the production apparatus 1 as illustrated in FIG. 1, the production apparatus 1A as illustrated in FIG. 2, and the production apparatus 1B as illustrated in FIG. 3. That is to say, the upper forming plate 24 is lifted to a position shown by broken lines in FIG. 1 to FIG. 3. Such method is more preferable than the method (ii) and the method (iii) in terms of easiness of flow of the lower lining paper sheet when the space between the forming plates 6 is expanded. However, the method (ii) or the method (iii) may be adopted for the purpose of making the cleaning of an apparatus easy, or other purposes.

(36) The space between the forming plates may be expanded to such an extent that the foreign bodies pass between a pair of forming plates. The specific space is not particularly limited, however it is preferable to expand the space by 2 to 4 cm wider than the original space from the reason that the time for expanding the space is made short to allow the foreign bodies to pass, and it is further preferably to expand the space by 2 cm wider. Moreover, it is more preferable that the speed of expanding the space between the forming plates is faster because the cut of the lining paper sheet is reduced more.

(37) The means for expanding and restoring the space between the forming plates is not particularly limited. For example, an actuator can be used that moves up and down at least one of a pair of upper and lower forming plates in response to an electric signal when an electric current is detected. The actuator will be explained specifically in the section of Apparatus for Producing Gypsum Board.

(38) [1-4] Restoration of Space Between Plates:

(39) In the production method of the present invention, the space between a pair of the forming plates is restored to the original space after the cause of conduction is removed. The expression after the cause of conduction is removed means after the foreign bodies that arise the cause of conduction (namely, the cut of the lining paper sheet, or the like) pass between the forming plates. The situation where the foreign bodies are caught between the forming plates again and the lining paper sheet is cut can be prevented by restoring the space between the forming plates to the original space after the foreign bodies pass between the forming plates. And, the production of the gypsum board (the step of obtaining a molded body depending on the space between the forming plates) is restarted. When such a method is adopted, it never occurs that the lining paper sheet is completely torn and the production is stopped. That is to say, it is not necessary to conduct complicated operation in which the foreign bodies are removed, then the lining paper sheet is supplied again between a pair of upper and lower forming plates, and the gypsum slurry is injected into the gap of the pair of upper and lower lining paper sheets to restart the production.

(40) Whether the cause of conduction is removed or not is evaluated by both the fact that the electric current has stopped flowing and the fact that the foreign bodies have passed between the forming plates. The fact that the electric current has stopped flowing can be detected by the electric current detector or the like which is electrically connected to the circuit. Examples of the method for restoring the space between the plates to the original space after the foreign bodies pass between the plates include a method in which the passing time required for the foreign objects to pass between the plates is determined from the feeding speed of the laminated body consisting of lining paper sheets and a gypsum slurry and the length of the forming plates, and the space between the plates is restored to the original space after the elapse of the passing time. Further, the examples also include a method in which the number of revolutions of the roll of a belt conveyor for feeding the laminated body is counted by a measuring roll, then the number of revolutions of the roll that corresponds to the time required for the foreign bodies to pass between the plates is determined from the relation between the number of revolutions of the roll and the feeding distance of the belt conveyor, and the space between plates is restored to the original space after the number of revolutions of the roll thus determined is counted.

(41) The speed of restoring the space between the forming plates is not specifically limited. However, it is preferable to set the speed so that there is not a risk that the upper or lower lining paper sheet is not cut or the gypsum slurry on the lower lining paper sheet overflows and leaks outside.

(42) [2] Apparatus for Producing Gypsum Board:

(43) The method for producing a gypsum board of the present invention can be conducted, for example, with the apparatus for producing a gypsum board of the present invention explained below. The apparatus for producing a gypsum board of the present invention includes: a pair of upper and lower forming plates; an electric current detector; and an actuator as constituent members. Hereinafter, explanation will be made for each constituent member separately.

(44) [2-1] Forming Plates:

(45) The production apparatus of the present invention includes a pair of upper and lower forming plates for forming a laminated material obtained by injecting a gypsum slurry into a gap between a pair of upper and lower lining paper sheets so that the laminated material has a thickness depending on the space between the plates. For example, any of the production apparatus 1 as illustrated in FIG. 1, the production apparatus 1A as illustrated in FIG. 2, and the production apparatus 1B as illustrated in FIG. 3 includes a pair of upper and lower forming plates 6 (lower forming plate 8 and upper forming plate 24) for forming a laminated material obtained by injecting the gypsum slurry 4 into the gap between a pair of upper and lower lining paper sheets 2 so that the laminated material has a thickness depending on the space between the plates.

(46) At least one of a pair of upper and lower forming plates in the production apparatus of the present invention has: a plate main body constituted from an electrically conductive material; and an embedded electrode embedded in the plate main body. With the embedded electrode, it becomes possible to detect the cut of the lining paper sheet early.

(47) For example, in the production apparatus 1 as illustrated in FIG. 1, the lower forming plate 8 has: the lower plate main body 10; and the lower embedded electrode 12 embedded in the lower plate main body 10 for the purpose of detecting the cut of the lower lining paper sheet 16. On the other hand, in the production apparatus 1A as illustrated in FIG. 2, the upper forming plate 24 has: the upper plate main body 26; and the upper embedded electrode 28 embedded in the upper plate main body 26 for the purpose of detecting the cut of the upper lining paper sheet 32. In order to detect the cut of both the lower lining paper sheet and the upper lining paper sheet, a structure may be made in which the lower forming plate 8 has: the lower plate main body 10; and the lower embedded electrode 12 embedded in in the lower plate main body 10 and the upper forming plate 24 has: the upper plate main body 26; and the upper embedded electrode 28 embedded in the upper plate main body 26, as shown in the production apparatus 1B as illustrated in FIG. 3.

(48) The plate main body is a member that constitutes a circuit by being electrically connected to the embedded electrode, and therefore it is necessary that the plate main body be constituted from an electrically conductive material. The kind of the electrically conductive material is not particularly limited. However, since the plate main body is an important member that determines the thickness of a molded body, it is necessary to avoid a change in shape attributable to wear as much as possible. Accordingly, it is preferable that the electrically conductive material that constitutes the plate main body is at least one material selected from the group consisting of iron materials, stainless steel materials, and aluminum materials, or a material obtained by applying hard chromium plating thereon. These materials are preferable in that these materials have a high rigidity and excellent wear resistance and size accuracy in addition to electric conductivity.

(49) It is preferable that a material that constitutes the embedded electrode is also at least one material selected from the group consisting of iron materials, stainless steel materials, and aluminum materials, or a material obtained by applying hard chromium plating thereon from the similar reason to that in the plate main body. The shape of the embedded electrode is not particularly limited and may be used as long as the shape has a width to cover the entire width of a gypsum board to be produced. The embedded electrodes having various kinds of shapes such as, for example, round rod-like, square rod-like, and sheet-like shapes can be used.

(50) The embedded electrode is electrically insulated by an insulator from the plate main body in which the embedded electrode is embedded. Thereby, it is possible to prevent a short circuit between the embedded electrode and the plain main body, and it is also possible to surely detect an electric current that flows between the embedded electrode and the plate main body.

(51) For example, in the production apparatus as illustrated in FIG. 1, the lower embedded electrode 12 and the lower plate main body 10 are electrically insulated by the insulator 14. On the other hand, in the production apparatus 1A as illustrated in FIG. 2, the upper embedded electrode 28 and the upper plate main body 26 are electrically insulated by the insulator 30. Further, in the production apparatus 1B as illustrated in FIG. 3, the lower embedded electrode 12 and the lower plate main body 10 are insulated by the insulator 14 and the upper embedded electrode 28 and the upper plate main body 26 are also insulated by the insulator 30.

(52) In the production apparatus of the present invention, not only the embedded electrode but also the insulator is embedded in the plate main body. Since the plate main body is an important member that determines the thickness of a molded body, it is necessary to avoid a change in shape attributable to wear also in the insulator that forms part of the plate main body as much as possible. Moreover, it is not preferable that the exchanging work of members becomes complicated as a result that the wear resistance between the insulator and the plate main body or the like is different to bring about, for example, a different exchange period for each member. Accordingly, a favorable wear resistance in addition to the insulation performance is required for the insulator. Moreover, since the insulator is a member that is embedded in the plate main body, it is preferable, for the purpose of preventing voids or level difference between the insulator and the plate main body or embedded electrode from occurring, that: (1) the insulator is constituted from a material which has a good processability and which can be processed with a high size accuracy; and (2) the insulator is constituted from a material with which the void or level difference is hard to occur due to a change in size over time.

(53) Conventionally, since it has been difficult to design an insulating material that satisfies the above-described requirements, it has been common general technical knowledge that a molded plate is constituted from a single material, and an idea of embedding an detection electrode inside the molded plate has not existed. For this reason, it is considered that a lower external electrode 138 for detecting the cut of paper has been arranged on a further downstream side of the downstream end of the forming plate (lower forming plate 108) as shown in the production apparatus 100 as illustrated in FIG. 4. In order to solve the above-described problem of the insulating material, it is preferable that the insulator is constituted from at least one material selected from the group consisting of phenol resin laminated plates with a cloth base material (also referred to as cloth-containing bakelite), phenol resin laminated plates with a paper base material (also referred to as paper-containing bakelite), epoxy resin-impregnated glass fiber cloth (also referred to as glass-epoxy resins), and epoxy resin-impregnated paper (also referred to as paper-epoxy resins). These materials can suitably be used because of favorable wear resistance, processability, and size accuracy in addition to insulation performance. It is particularly preferable to use the phenol resin laminated plate with a cloth base material that is excellent in wear resistance, processability, and size accuracy among the above-described materials.

(54) In the production apparatus of the present invention, the embedded electrode is embedded so as for a portion thereof to be exposed on the surface of the plate main body making contact with the lining paper sheet. In this case, it is preferable that the embedded electrode is arranged so that there is no level difference between the surface of the plate main body making contact with the lining paper sheet and the surface of the embedded electrode, and is arranged so that there is no gap between the embedded electrode and the insulator that will be mentioned later.

(55) For example, in the production apparatus 1 as illustrated in FIG. 1, the rod-like lower embedded electrode 12 is filled in the groove portion of the insulator 14 having an approximately U-shaped section, and is embedded so as for a portion thereof (upper face) to be exposed on the surface of the lower plate main body 10. On the other hand, in the production apparatus 1A as illustrated in FIG. 2, the rod-like upper embedded electrode 28 is filled in the groove portion of the insulator 30 having an approximately U-shaped section, and is embedded so as for a portion thereof (bottom face) to be exposed on the surface of the upper plate main body 26. Further, in the production apparatus 1B as illustrated in FIG. 3, the rod-like lower embedded electrode 12 is filled in the groove portion of the insulator 14 having an approximately U-shaped section, and is embedded so as for a portion thereof (upper face) to be exposed on the surface of the lower plate main body 10. Furthermore, the rod-like upper embedded electrode 28 is filled in the groove portion of the insulator 30 having an approximately U-shaped section, and is embedded so as for a portion thereof (bottom face) to be exposed on the surface of the upper plate main body 26.

(56) It is preferable that the forming plates have an embodiment in which a taper portion whose plate thickness at a position in the taper portion becomes thinner as the position approaches upstream ends of the forming plates is formed in at least one of the pair of upper and lower forming plates, and a space between the pair of the forming plates at a position in the taper portion becomes larger, due to the taper portion, as the position approaches the upstream ends of the forming plates. When such an embodiment is made, the holdup of the gypsum slurry is prepared immediately before the starting position of forming, thereby making it possible to keep the holdup volume of the gypsum slurry always constant. Accordingly, the gypsum slurry is molded while keeping a state in which the air is trapped therein, making it possible to effectively prevent a situation where gypsum boards in which internal voids are formed are produced. Thereby, it is possible to solve the problems of gypsum boards, such as bulging and denting, lowering of the smoothness, and dropping out of nails and screws (fixing failure of boards) when the gypsum boards are fixed, attributable to the above-described internal voids.

(57) For example, in the production apparatus 1 as illustrated in FIG. 1, the production apparatus 1A as illustrated in FIG. 2, the production apparatus 1B as illustrated in FIG. 3, and the production apparatus 1C as illustrated in FIG. 5, the embodiment is the one in which a taper portion whose plate thickness at a position in the taper portion becomes thinner as the position approaches the upstream end (edge on the upstream side of the plate) of the lower forming plate 8 is formed in the lower forming plate 8, and a space between the pair of the forming plates 6 at a position in the taper portion becomes larger, due to the taper portion, as the position approaches the upstream end. However, a taper portion whose plate thickness at a position in the taper portion becomes thinner as the position approaches upstream end of a forming plate may be formed in the upper forming plate, or the taper portions may be formed in both the lower forming plate and the upper forming plate (not shown in the figures).

(58) In the production apparatus of the present invention, it is preferable that the embedded electrode is embedded at a portion on a downstream side of the starting position of forming in the plate main body, and it is further preferable that the embedded electrode is embedded, in the plate main body, at a portion within a range from the starting position of forming to a position on the downstream side of the starting position of forming by 50 mm. The space between plates at the starting position of forming is narrower than the space between plates on the upstream side of the starting position of forming for the purpose of forming a laminated material obtained by injecting a gypsum slurry into a gap between a pair of upper and lower lining paper sheets so as to form the thickness of the laminated material depending on the space between plates. Therefore, the starting position of forming is a region where foreign bodies are liable to be caught and where there is a high possibility that the cut of the lining paper sheet is liable to occur. Accordingly, in order to detect the cut of the lining paper sheet early, it can be said that it is preferable to arrange the embedded electrode at a position near the starting position of forming. Specifically, it is particularly preferable that the embedded electrode is embedded at a portion within a range from the starting position of forming to a position on the downstream side of the starting position of forming by 25 mm.

(59) On the other hand, there is a time lag from the time when the lining paper sheet is cut to the time when the gypsum slurry begins to leak out. Accordingly, it is more preferable that the embedded electrode is embedded at a position somewhat downstream side of the starting position of forming in the plate main body than that the embedded electrode is embedded at the starting position of forming in the plate main body. Moreover, when the production speed of the gypsum board becomes high, the position where the leak out of the gypsum slurry can be detected after the lining paper sheet is cut recedes from the starting position of forming. Accordingly, in the case where high speed production is conducted, it is preferable that the embedding electrode is embedded at a portion on further downstream side in the plate main body than in the case where low speed production is conducted. Specifically, it is preferable that the embedded electrode is embedded, in the plate main body, at a portion on further downstream side of a position on the downstream side of the starting position of forming by 15 mm.

(60) As described above, it is necessary that an appropriate embedding position of the embedded electrode be determined, in the plate main body, within a portion on the downstream side of the starting position of forming (particularly, a portion within a range from the starting position of forming to a position on the downstream side of the starting position of forming by 50 mm) considering the production speed.

(61) In addition, the starting position of forming means a position where forming of the laminated material obtained by injecting a gypsum slurry into a gap between a pair of lining paper sheets is started, and specifically means a position on the most downstream side of the following (1) and the following (2). Hereinafter, explanation will be made on the starting position of forming with reference to FIG. 6A to FIG. 6E. In addition, the embedded electrode, the insulator, and so on are omitted, and only the shape of the forming plates are illustrated in FIG. 6A to FIG. 6E for the convenience of drawing. Moreover, the thick arrow in FIG. 6A to FIG. 6E shows a transportation direction (namely, downstream direction) of the laminated material.

(62) (1) a position of an upstream end of either one of the pair of upper and lower forming plates; and

(63) (2) a position of a downstream end of a taper portion in an embodiment wherein the taper portion whose plate thickness at a position in the taper portion becomes thinner as the position approaches upstream ends of the forming plates is formed in at least one of the pair of upper and lower forming plates, and a space between the pair of the forming plates at a position in the taper portion becomes larger, due to the taper portion, as the position approaches the upstream ends of the forming plates.

(64) The production apparatus of the present invention is a production apparatus for obtaining a molded body having a thickness depending on the space between plates by allowing the laminated material to pass between a pair of upper and lower forming plates. Accordingly, in forming the laminated body, a pair of upper and lower forming plates are arranged so as to face each other, and forming is started at a position where the space of the plates is sufficiently narrowed to such an extent that forming is possible. In the case of an embodiment where the taper portion is not formed on the upstream side of any of the pair of upper and lower forming plates (upper forming plate and lower forming plate), a position of the upstream end of any one of the pair of upper and lower forming plates becomes the starting position of forming.

(65) In the example as illustrated in FIG. 6A for example, the position of the upstream end 24a of the upper forming plate 24 and the position of the upstream end 8a of the lower forming plate 8 are located on one straight line. That is to say, on the downstream side of the upstream ends 24a and 8a, a pair of upper and lower forming plates 6 are arranged so as to face each other, and the space between plates are sufficiently narrowed to such an extent that forming is possible. Accordingly, the position of the upstream end 24a of the upper forming plate 24 (or the position of the upstream end 8a of the lower forming plate 8) becomes the starting position of forming P.

(66) Moreover, in the example as illustrated in FIG. 6B, the pair of upper and lower forming plates are arranged so that the upstream end 8a of the lower forming plate 8 protrudes on the upstream side of the upstream end 24a of the upper forming plate 24. In the case of such an embodiment, the pair of upper and lower forming plates 6 are arranged so as to face each other on the downstream side of the upstream end 24a of the upper forming plate 24, and the space between the plates is sufficiently narrowed to such an extent that forming is possible. Accordingly, the position of the upstream end 24a of the upper forming plate 24 becomes the starting position of forming P.

(67) In the case of an embodiment in which a taper portion whose plate thickness at a position in the taper portion becomes thinner as the position approaches upstream ends of the forming plates is formed in at least one of the pair of upper and lower forming plates, and a space between the pair of the forming plates at a position in the taper portion becomes larger, due to the taper portion, as the position approaches the upstream ends of the forming plates, the position of the downstream end of the taper portion can also become the starting position of forming in addition to the position of the upstream ends of the pair of upper and lower forming plates. Here, the space between the pair of upper and lower forming plates at a position in the taper portion becomes larger, due to the taper portion, as the position approaches the upstream end means, in other words, that the slope face of the taper portion is formed on the side of a face that makes contact with the lining paper sheet in the forming plate.

(68) In the example as illustrated in FIG. 6C for example, the position of the upstream end 24a of the upper forming plate 24 and the position of the upstream end 8a of the lower forming plate 8 are located on one straight line. That is to say, a pair of upper and lower forming plates 6 are arranged so as to face each other on the downstream side of the upstream ends 24a and 8a. However, the space between the pair of upper and lower forming plates 6 becomes larger at the position of the upstream end 8a of the lower forming plate 8 due to the taper portion 8b, and the space is not sufficiently narrowed to such an extent that forming is possible. Accordingly, the position of the downstream end 8c of the taper portion 8b where space between the pair of upper and lower forming plates 6 is sufficiently narrowed becomes the starting position of forming P.

(69) Moreover, also in the example as illustrated in FIG. 6D, the position of the upstream end 24a of the upper forming plate 24 and the position of the upstream end 8a of the lower forming plate 8 are located on one straight line, and a pair of upper and lower forming plates 6 are arranged so as to face each other on the downstream side of the upstream ends 24a and 8a. However, the space between the pair of upper and lower forming plates 6 becomes larger at the position of the upstream end 24a of the upper forming plate 24 due to the taper portion 24b, and the space is not sufficiently narrowed to such an extent that forming is possible. Accordingly, the position of the downstream end 24c of the taper portion 24b where space between the pair of upper and lower forming plates 6 is sufficiently narrowed becomes the starting position of forming P.

(70) Further in the example as shown in FIG. 6E, it can be said that the upper and lower forming plates are arranged so that the upstream end 8a of the lower forming plate 8 protrudes on the upstream side of the upstream end 24a of the upper forming plate 24 and a pair of upper and lower forming plates 6 are arranged so as to face each other on the downstream side of the upstream end 24a of the upper forming plate 24. However, the space between the pair of forming plates 6 becomes larger due to the taper portion 24b of the upper forming plate 24 and the taper portion 8b of the lower forming plate 8 at the position of the upstream end 24a of the upper forming plate 24, and the space is not sufficiently narrowed to such an extent that forming is possible. Accordingly, the position of the downstream end 24c of the taper portion 24b where the space between the pair of upper and lower forming plates 6 is sufficiently narrowed becomes the starting point of forming P.

(71) [2-2] Circuit:

(72) In the apparatus for producing a gypsum board of the present invention, a circuit is constituted by electrically connecting the embedded electrode and the plate main body in which the embedded electrode is embedded.

(73) For example, the production apparatus 1 as illustrated in FIG. 1 is an example in which the circuit 18 is constituted by electrically connecting the lower embedded electrode 12, the lower plate main body 10, and the pour source D1. On the other hand, the production apparatus 1A as illustrated in FIG. 2 is an example in which the circuit 34 is constituted by electrically connecting the upper embedded electrode 28 and the upper plate main body 26. Further, as in the production apparatus 1B as illustrated in FIG. 3, the circuit 34 may be constituted by electrically connecting the upper embedded electrode 28 and the upper plate main body 26 in addition to the circuit 18 constituted by electrically connecting the lower embedded electrode 12 and the lower plate main body 10.

(74) Furthermore, as illustrated in FIG. 5, the circuit 40 including the lower external electrode 38, the lower plate main body 10, and the power source D3 may be constituted in addition to the circuit 18. In addition, the circuit 40 including the lower external electrode 38 may be formed together with the circuit 34 including the upper embedded electrode 28 as illustrated in FIG. 2 (not shown in the figure). Moreover, the circuit 40 may be formed together with the circuit 18 including the lower embedded electrode 12 as illustrated in FIG. 3 and the circuit 34 including the upper embedded electrode 28 (not shown in the figure).

(75) [2-3] Electric Current Detector:

(76) The apparatus for producing a gypsum board of the present invention includes an electric current detector electrically connected to the circuit that connects the embedded electrode and the plate main body. With the electric current detector, the cut of the lining paper sheet, or the like can be detected.

(77) For example, the production apparatus 1 as illustrated in FIG. 1 includes an electric current detector 20 that is electrically connected to the circuit 18, and makes it possible to detect a current that flows between the lower embedded electrode 12 and the lower plate main body 10. On the other hand, the production apparatus 1A as illustrated in FIG. 2 includes an electric current detector 20 that is electrically connected to the circuit 34, and makes it possible to detect a current that flows between the upper embedded electrode 28 and the upper plate main body 26. Further, the production apparatus 1B as illustrated in FIG. 3 includes an electric current detector 20 that is electrically connected to both the circuit 18 and the circuit 34. Thereby, it becomes possible to detect both the current that flows between the lower embedded electrode 12 and the lower plate main body 10 and the current that flows between the upper embedded electrode 28 and the upper plate main body 26. In the case where a plurality of circuits exist, a plurality of circuits 18 and 34 may share the electric current detector 20 as illustrated in FIG. 3.

(78) [2-4] Actuator:

(79) The apparatus for producing a gypsum board of the present invention includes an actuator that moves at least one of forming plates up and down in response to an electric signal from the electric current detector.

(80) For example, the production apparatus 1 as illustrated in FIG. 1, the production apparatus 1A as illustrated in FIG. 2, the production apparatus 1B as illustrated in FIG. 3, and the production apparatus 1C as illustrated in FIG. 5 include an actuator 22 that moves the upper forming plate 24 up and down in response to an electric signal from the electric current detector 20. However, the production apparatus of the present invention may be a production apparatus including an actuator that moves the lower forming plate up and down, or may be a production apparatus including an actuator that moves both the upper forming plate and the lower forming plate up and down (not shown in the figure).

(81) The actuator may be a device that drives the forming plate up and down depending on the electric current detector. Specific examples of the kind of the device include, but not particularly limited to, an air cylinder, an oil cylinder, a servomotor, and so on.

EXAMPLES

(82) Hereinafter, the present invention will be explained in more specifically by Examples and Comparative Examples. However, the present invention is not limited to only the constitution of the following Examples.

Example 1

(83) As a production apparatus of Example 1, the production apparatus 1 as illustrated in FIG. 1 was manufactured. A gypsum board to be produced was determined to be a gypsum board having a width of 910 mm and a thickness of 9.5 mm. In the production apparatus 1, the lining paper sheet 2 (upper lining paper sheet 32 and lower lining paper sheet 16) is transferred from the right-hand side to the left-hand side in the figure. The production apparatus is constituted so that the gypsum slurry 4 is continuously supplied on the lower lining paper sheet 16. The roll 36 is a roll for changing the supplying direction of the upper lining paper sheet 32.

(84) [1-1] Forming Plates:

(85) The production apparatus including a pair of upper and lower forming plates 6 (the lower forming plate 8 and upper forming plate 24) was used. The lower forming plate 8 having: the lower plate main body 10; and the lower embedded electrode embedded in the lower plate main body 10 was used. The upper plate main body 26 and the lower plate main body 10 were constituted from a material obtained by applying hard chromium plating on an iron material. The lower embedded electrode 12 was made of a stainless material, and had a square section of 6 mm6 mm and a square rod-like shape having a length of 1200 mm.

(86) The lower embedded electrode 12 and the lower plate main body 10 were electrically insulated by the insulator 14. The insulator 14 was constituted from a phenol resin laminated plate with a cloth base material. The insulator had an approximately U-shaped section and an approximately square rod-like shape in which a groove portion was formed. The lower embedded electrode 12 was filled in the groove portion of the insulator 14 and was embedded so that a portion thereof (upper face) was exposed on the surface of the lower plate main body 10. The insulator 14 was arranged on the front and behind sides of the lower embedded electrode 12 with a width of 5 mm to electrically insulate the lower embedded electrode 12. The lower embedded electrode 12 was embedded at a portion ranging from a position on the downstream side of the starting position of forming by 15 mm to a position on the downstream side of the starting position of forming by 21 mm in the lower plate main body 10. That is to say, the lower embedded electrode 12 was exposed on the surface of the lower plate main body 10 over a width of 6 mm.

(87) The taper portion was formed on the upstream end side of the lower forming plate 8. The length of the taper portion was determined to be 50 mm, and the height of the taper portion was determined to be 4 mm. On the downstream side of the taper portion, the lower forming plate 8 and the upper forming plate 24 are arranged so as to face each other, and the forming space is formed so that the space between plates is sufficiently narrowed to such an extent that forming is possible. The forming space is formed from the starting position of forming to a position on the downstream side of the starting position of forming by 300 mm.

(88) [1-2] Circuit:

(89) The lower embedded electrode 12, the lower plate main body 10, and the power source D1 were electrically connected to constitute the circuit 18.

(90) [1-3] Electric Current Detector:

(91) The electric current detector 20 was electrically connected to the circuit 18.

(92) [1-4] Actuator:

(93) The actuator 22 moving the upper forming plate 24 up and down in response to an electric signal from the electric current detector 20 was installed. An air cylinder was used as the actuator.

(94) [1-5] Production of Gypsum Boards:

(95) Gypsum boards were produced using the above-described production apparatus. The production speed of the gypsum board was determined to be 150 m/min. The production apparatus was operated for 20 days under the condition of continuously operating the production apparatus for 24 hours per day to find that the number of the cases where the lining paper sheet was completely torn to stop continuous production was only one.

Example 2

(96) As a production apparatus of Example 2, the production apparatus 1A as illustrated in FIG. 2 was manufactured. The production apparatus was manufactured in the same manner as in the production apparatus of Example 1 except the matters described below.

(97) [2-1] Forming Plates:

(98) The production apparatus including a pair of upper and lower forming plates 6 (lower forming plate 8 and upper forming plate 24) was used. The upper plate main body 26 and the lower plate main body 10 were constituted from a material obtained by applying hard chromium plating on an iron material. The lower embedded electrode was not arranged in the lower forming plate 8, and the upper embedded electrode 28 was arranged in the upper forming plate 24. The upper embedded electrode 28 was made of a stainless material, and had a square section of 6 mm6 mm and a square rod-like shape having a length of 1200 mm.

(99) The upper embedded electrode 28 and the upper plate main body 26 were electrically insulated by the insulator 30. The insulator 30 was constituted from a phenol resin laminated plate with a cloth base material. The insulator had an approximately U-shaped section and an approximately square rod-like shape in which a groove portion was formed. The upper embedded electrode 28 was filled in the groove portion of the insulator 30, and was embedded so that a portion (bottom face) thereof was exposed on the surface of the upper plate main body 26. The insulator 30 was arranged on the front and behind sides of the upper embedded electrode 28 with a width of 5 mm to electrically insulate the upper embedded electrode 28. The upper embedded electrode 28 was embedded at a portion ranging from a position on the downstream side of the forming by 15 mm to a position on the downstream side of the starting position of forming by 21 mm in the upper plate main body 26. That is to say, the upper embedded electrode 28 was exposed on the surface of the upper plate main body 26 over a width of 6 mm.

(100) [2-2] Circuit:

(101) The upper embedded electrode 28, the upper plate main body 26, and the power source D2 were electrically connected to constitute the circuit 34.

(102) [2-3] Electric Current Detector:

(103) The electric current detector 20 was connected to the circuit 34.

(104) [2-4] Production of Gypsum Boards:

(105) Gypsum boards were produced using the above-described production apparatus. The production speed of the gypsum board was determined to be 150 m/min. The production apparatus was operated for 20 days under the condition of continuously operating the production apparatus for 24 hours per day to find that the number of the cases where the lining paper sheet was completely torn to stop continuous production was only two.

Example 3

(106) As a production apparatus of Example 3, the production apparatus 1B as illustrated in FIG. 3 was manufactured. The production apparatus was manufactured in the same manner as in the production apparatus of Example 1 except the matters described below.

(107) [3-1] Forming Plates:

(108) The lower forming plate 8 was constituted in the same manner as in the production apparatus of Example 1. The lower embedded electrode 12 was embedded at a portion ranging from a position on the downstream side of the starting position of forming by 15 mm to a position on the downstream side of the starting position of forming by 21 mm in the lower plate main body 10. The upper forming plate 24 was constituted in the same manner as in the production apparatus of Example 2.

(109) [3-2] Circuit:

(110) The lower embedded electrode 12, the lower plate main body 10, and the power source D1 were electrically connected to constitute the circuit 18, and the upper embedded electrode 28, the upper plate main body 26, and the power source D2 were electrically connected to constitute the circuit 34.

(111) [3-3] Electric Current Detector:

(112) The electric current detector 20 was electrically connected to the circuit 18 and the circuit 34.

(113) [3-4] Production of Gypsum Boards:

(114) Gypsum boards were produced using the above-described production apparatus. The production speed of the gypsum board was determined to be 150 m/min. The production apparatus was operated for 20 days under the condition of continuously operating the production apparatus for 24 hours per day to find that the number of the cases where the lining paper sheet was completely torn to stop continuous production was only one.

Example 4

(115) As a production apparatus of Example 4, the production apparatus 1B as illustrated in FIG. 3 was manufactured. The production apparatus was manufactured in the same manner as in the production apparatus of Example 1 except the matters described below.

(116) [4-1] Forming Plates:

(117) The lower forming plate 8 was constituted in the same manner as in the production apparatus of Example 1 except the position of the lower embedded electrode 12. The lower embedded electrode 12 was embedded at a portion ranging from a position on the downstream side of the starting position of forming by 25 mm to a position on the downstream side of the starting position of forming by 31 mm in the lower main plate main body 10. The upper forming plate 24 was constituted in the same manner as in the production apparatus of Example 2.

(118) [4-2] Circuit:

(119) The lower embedded electrode 12, the lower plate main body 10, and the power source D1 were electrically connected to constitute the circuit 18, and the upper embedded electrode 28, the upper plate main body 26, and the power source D2 were electrically connected to constitute the circuit 34.

(120) [4-3] Electric Current Detector:

(121) The electric current detector 20 was electrically connected to the circuit 18 and the circuit 24.

(122) [4-4] Production of Gypsum Boards:

(123) Gypsum boards were produced using the above-described production apparatus. The production speed of the gypsum board was determined to be 150 m/min. The production apparatus was operated for 20 days under the condition of continuously operating the production apparatus for 24 hours per day to find that there were no cases where the lining paper sheet was completely torn and there were also no cases where the continuous production was stopped.

Comparative Example 1

(124) As a production apparatus of Comparative Example 1, the production apparatus 100 as illustrated in FIG. 4 was manufactured. The production apparatus was manufactured in the same manner as in the production apparatus of Example 1 except the matters described below.

(125) [5-1] Forming Plates:

(126) The lower embedded electrode was not arranged in the lower forming plate 108. Instead, the lower external electrode 138 was arranged at a position apart from the end (downstream end) of the lower forming plate 108 by 10 mm on the downstream side. The lower external electrode 138 was arranged in a state where the lower external electrode was electrically isolated from the surroundings. The lower external electrode 138 was made of an iron material obtained by applying hard chromium plating thereon, and had a square section of 24 mm24 mm and a square rod-like shape having a length of 1200 mm. The upper forming plate 124 was constituted in the same manner as in the upper forming plate 24 of the production apparatus of Example 1.

(127) [5-2] Circuit:

(128) The lower external electrode 138, the lower forming plate 108, and the power source D3 were electrically connected to constitute the circuit 140.

(129) [5-3] Electric Current Detector:

(130) The electric current detector 120 was electrically connected to the circuit 140.

(131) [5-4] Production of Gypsum Boards:

(132) Gypsum boards were produced using the above-described production apparatus. The production speed of the gypsum board was determined to be 150 m/min. The production apparatus was operated for 20 days under the condition of continuously operating the production apparatus for 24 hours per day to find that the number of the cases where the lining paper sheet was completely torn to stop continuous production reached 10.

INDUSTRIAL APPLICABILITY

(133) The method and apparatus for producing a gypsum board of the present invention can suitably be used for producing gypsum boards useful as building materials such as ceiling materials, wall materials, flooring materials.

REFERENCE SIGNS LIST

(134) 1A, 1B and 1C (Gypsum board) Production apparatus 2 Lining paper sheet 4 Gypsum slurry 6 Forming plate 8 Lower forming plate 8a Upstream end 8b Taper portion 8c Downstream end 10 Lower plate main body 12 Lower embedded electrode 14 Insulator 16 Lower lining paper sheet 18 Circuit 20 Electric current detector 22 Actuator 24 Upper forming plate 24a Upstream end 24b Taper portion 24c Downstream end 26 Upper plate main body 28 Upper embedded electrode 30 Insulator 32 Upper lining paper sheet 34 Circuit 36 Roll 38 Lower external electrode 40 Circuit 100 (Gypsum board) Production Apparatus 104 Gypsum slurry 108 Lower forming plate 116 Lower lining paper sheet 120 Electric current detector 122 Air cylinder 124 Upper forming plate 132 Upper lining paper sheet 136 Roll 138 Lower external electrode 140 Circuit C Ground D, D1, D2, and D3 Power source P Starting position of forming